Abstract: An illustrative example sensor device includes a plurality of range finders that each have an emitter configured to emit a selected type of radiation and a detector configured to detect the selected type of radiation reflected from an object. A plurality of cameras are configured to generate an image of an object based upon receiving the selected type of radiation from the object. A processor is configured to determine a distance between the sensor device and an object based on at least two of the images, wherein the images are each from a different camera.

Abstract: A method of assembling a camera includes the steps of determining a focused-position of a lens relative to an imager where an image is focused on the imager, determining a first-factor indicative of focus quality at a central-portion of the imager, and determining a second-factor indicative of focus quality at an outer-portion of the imager. The outer-portion is characterized as displaced radially outward from the central-portion. The method also includes the steps of determining an actual-ratio of the first-factor and the second-factor, and determining an offset-position of the lens relative to the imager based on the focused-position, a ratio-difference between the actual-ratio and a desired-ratio, and an expansion-characteristic of an adhesive that is used to fixedly couple the lens to the imager. The method also includes the step of applying the adhesive to fixedly couple the lens to the imager while the lens is in the offset-position.

Abstract: A method of assembling a camera includes the steps of determining a focused-position of a lens relative to an imager where an image is focused on the imager, determining a first-factor indicative of focus quality at a central-portion of the imager, and determining a second-factor indicative of focus quality at an outer-portion of the imager. The outer-portion is characterized as displaced radially outward from the central-portion. The method also includes the steps of determining an actual-ratio of the first-factor and the second-factor, and determining an offset-position of the lens relative to the imager based on the focused-position, a ratio-difference between the actual-ratio and a desired-ratio, and an expansion-characteristic of an adhesive that is used to fixedly couple the lens to the imager. The method also includes the step of applying the adhesive to fixedly couple the lens to the imager while the lens is in the offset-position.

Abstract: A ground-classifier system that classifies ground-cover proximate to an automated vehicle includes a lidar, a camera, and a controller. The lidar that detects a point-cloud of a field-of-view. The camera that renders an image of the field-of-view. The controller is configured to define a lidar-grid that segregates the point-cloud into an array of patches, and define a camera-grid that segregates the image into an array of cells. The point-cloud and the image are aligned such that a patch is aligned with a cell. A patch is determined to be ground when the height is less than a height-threshold. The controller is configured to determine a lidar-characteristic of cloud-points within the patch, determine a camera-characteristic of pixels within the cell, and determine a classification of the patch when the patch is determined to be ground, wherein the classification of the patch is determined based on the lidar-characteristic and the camera-characteristic.

Abstract: An illustrative example camera device includes a sensor that is configured to detect radiation. A first portion of the sensor has a first field of vision and is used for a first imaging function. A distortion correction prism directs radiation outside the first field of vision toward the sensor. A lens element between the distortion correcting prism and the sensor includes a surface at an oblique angle relative to a sensor axis. The lens element directs radiation from the distortion correcting prism toward a second portion of the sensor that has a second field of vision and is used for a second imaging function. The sensor provides a first output for the first imaging function based on radiation detected at the first portion of the sensor. The sensor provides a second output for the second imaging function based on radiation detection at the second portion.

Abstract: A dual-focus camera suitable for use on an automated includes an imager, a lens-assembly, and a negative-meniscus-lens (NML). The imager is used to detect an image of a field-of-view. The lens-assembly is used to direct the image from the field-of-view toward the imager. The lens-assembly is characterized as focused at a first-distance in the field-of view. The negative-meniscus-lens is interposed between the imager and the lens-assembly. The negative-meniscus-lens is configured to focus a portion of the image onto the imager. The portion is characterized as less than a whole of the image and focused at a second-distance in the field-of-view independent from the first-distance.

Abstract: A camera system suitable for use on an automated vehicle, includes an imager used to detect an image of a field-of-view of the system, a light-shield operable to block a portion of the image from being received by the imager, and a controller in communication with the imager and the light-shield. The controller is configured to position the light-shield in a line-of-sight between a bright-spot and the imager.

Abstract: An illustrative example method of making a camera includes assembling a plurality of lens elements, a sensor, and a housing to establish an assembly with each of the lens elements and the sensor at least partially in the housing. The assembly is then situated adjacent a circuit board substrate. At least the sensor is secured to the circuit board substrate using surface mount technology (SMT) and the assembly becomes fixed relative to the circuit board substrate.

Abstract: An illustrative example camera device includes a sensor that is configured to detect radiation. A first portion of the sensor has a first field of vision and is used for a first imaging function. A distortion correction prism directs radiation outside the first field of vision toward the sensor. A lens element between the distortion correcting prism and the sensor includes a surface at an oblique angle relative to a sensor axis. The lens element directs radiation from the distortion correcting prism toward a second portion of the sensor that has a second field of vision and is used for a second imaging function. The sensor provides a first output for the first imaging function based on radiation detected at the first portion of the sensor. The sensor provides a second output for the second imaging function based on radiation detection at the second portion.

Abstract: An integrated camera, ambient light detection, and rain sensor assembly suitable for installation behind a windshield of a driver operated vehicle or an automated vehicle includes an imager-device. The imager-device is formed of an array of pixels configured to define a central-portion and a periphery-portion of the imager-device. Each pixel of the array of pixels includes a plurality of sub-pixels. Each pixel in the central-portion is equipped with a red/visible/visible/visible filter (RVVV filter) arranged such that each pixel in the central-portion includes a red sub-pixel and three visible-light sub-pixels. Each pixel in the periphery-portion is equipped with a red/green/blue/near-infrared filter (RGBN filter) arranged such that each pixel in the periphery-portion includes a red sub-pixel, a green sub-pixel, a blue sub-pixel, and a near-infrared sub-pixel.

Abstract: A multiple imager camera includes a block, an imager, and an alignment apparatus. The block is configured to direct an image to a plurality of imagers located proximate to a plurality of apertures defined by the block. The imager of the plurality of imagers is configured to receive the image through an aperture of the plurality of apertures. The alignment apparatus is interposed between the block and the imager. The alignment apparatus is configured to allow for six degrees of freedom to align the imager with the image. The six degrees of freedom include adjustment along a x-axis, a y-axis, and a z-axis of the aperture, and adjustment about a pitch-axis, a yaw-axis, and a roll-axis of the aperture. The alignment apparatus is further configured to fixedly couple the imager to the block after the imager is aligned with the image.

Abstract: An integrated camera, ambient light detection, and rain sensor assembly suitable for installation behind a windshield of a driver operated vehicle or an automated vehicle includes an imager-device. The imager-device is formed of an array of pixels configured to define a central-portion and a periphery-portion of the imager-device. Each pixel of the array of pixels includes a plurality of sub-pixels. Each pixel in the central-portion is equipped with a red/visible/visible/visible filter (RVVV filter) arranged such that each pixel in the central-portion includes a red sub-pixel and three visible-light sub-pixels. Each pixel in the periphery-portion is equipped with a red/green/blue/near-infrared filter (RGBN filter) arranged such that each pixel in the periphery-portion includes a red sub-pixel, a green sub-pixel, a blue sub-pixel, and a near-infrared sub-pixel.

Abstract: An optical sensor system adapted to operate through a window of a vehicle includes a lens, a plurality of optoelectronic devices, and an optical device. The lens is configured to direct light from a field-of-view toward a focal plane. The plurality of optoelectronic devices are arranged proximate to the focal plane. The plurality of optoelectronic devices includes a first optoelectronic device operable to detect an image from a first portion of the field-of-view, and a second optoelectronic device operable to detect light from a second portion of the field-of-view distinct from the first portion. The optical device is configured to direct light from outside the field-of-view toward the second portion.

Abstract: An optical sensor system that includes a master lens, an optical diffuser, and a plurality of optoelectronic devices. The master lens is positioned on the vehicle to observe a field of view about the vehicle. An optical diffuser is located proximate to a focal plane of the master lens. The diffuser is configured to display an image of the field of view from the master lens. A first optoelectronic device generates a first video signal indicative of images on a first portion of the diffuser. A second optoelectronic device generates a second video signal indicative of images on a second portion of the diffuser. The optoelectronic devices may be sensitive to distinct ranges of wavelength. The second portion substantially overlaps the first portion such that the image captured by the first optoelectronic device is substantially the same as the image captured by the second optoelectronic device.

Abstract: An optical sensor system adapted to operate through a window of a vehicle includes a lens, a plurality of optoelectronic devices, and an optical device. The lens is configured to direct light from a field-of-view toward a focal plane. The plurality of optoelectronic devices are arranged proximate to the focal plane. The plurality of optoelectronic devices includes a first optoelectronic device operable to detect an image from a first portion of the field-of-view, and a second optoelectronic device operable to detect light from a second portion of the field-of-view distinct from the first portion. The optical device is configured to direct light from outside the field-of-view toward the second portion.

Abstract: A multiple imager camera includes a block, an imager, and an alignment apparatus. The block is configured to direct an image to a plurality of imagers located proximate to a plurality of apertures defined by the block. The imager of the plurality of imagers is configured to receive the image through an aperture of the plurality of apertures. The alignment apparatus is interposed between the block and the imager. The alignment apparatus is configured to allow for six degrees of freedom to align the imager with the image. The six degrees of freedom include adjustment along a x-axis, a y-axis, and a z-axis of the aperture, and adjustment about a pitch-axis, a yaw-axis, and a roll-axis of the aperture. The alignment apparatus is further configured to fixedly couple the imager to the block after the imager is aligned with the image.

Abstract: A system, controller, and method for aligning a stereo camera of a vehicle mounted object detection system that includes a first camera and a second camera mounted spaced apart on a vehicle. An image from each camera at two different times is used to determine an observed displacement of an object relative to the vehicle. A predicted displacement of the object relative to the vehicle is also determined using either a difference of vehicle position measured based on other vehicle measurements or GPS, or a difference of size of the object in images taken at the two different times. Alignment is provided by determining a triangulation correction based on a difference of the observed displacement and the predicted displacement to correct for misalignment of the cameras.

Abstract: An image system configured to record a scanned image of an area. The system includes a single two-dimensional (2D) imager and a rotatable mirror. The 2D imager is formed of a two-dimensional (2D) array of light detectors. The 2D imager is operable in a line-scan mode effective to individually sequence an activated line of light detectors at a time. The rotatable mirror is configured to rotate about an axis parallel to a plane defined by the rotatable mirror. The rotation is effective to vary an angle of the rotatable mirror to pan a projected image of the area across the 2D imager. The angle of the rotatable mirror and the activated line of the 2D imager are synchronized such that the scanned image recorded by the 2D imager is inverted with respect to the projected image.

Abstract: An optical sensor system that includes a master lens, an optical diffuser, and a plurality of optoelectronic devices. The master lens is positioned on the vehicle to observe a field of view about the vehicle. An optical diffuser is located proximate to a focal plane of the master lens. The diffuser is configured to display an image of the field of view from the master lens. A plurality of optoelectronic devices is configured to view the diffuser. A first optoelectronic device generates a first video signal indicative of images on a first portion of the diffuser. A second optoelectronic device generates a second video signal indicative of images on a second portion of the diffuser. Optionally, the first optoelectronic device is sensitive to a first light wavelength range, and the second optoelectronic device is sensitive to a second light wavelength range distinct from the first light wavelength range.

Abstract: An image system configured to record a scanned image of an area. The system includes a single two-dimensional (2D) imager and a rotatable mirror. The 2D imager is formed of a two-dimensional (2D) array of light detectors. The 2D imager is operable in a line-scan mode effective to individually sequence an activated line of light detectors at a time. The rotatable mirror is configured to rotate about an axis parallel to a plane defined by the rotatable mirror. The rotation is effective to vary an angle of the rotatable mirror to pan a projected image of the area across the 2D imager. The angle of the rotatable mirror and the activated line of the 2D imager are synchronized such that the scanned image recorded by the 2D imager is inverted with respect to the projected image.